Retinal birefringence scanning

Retinal birefringence scanning (RBS) is a method for detection the central fixation of the eye. The method can be used in pediatric ophthalmology for screening purposes. By simultaneously measuring the central fixation of both eyes, small- and large-angle strabismus can be detected. The method is non-invasive and requires little cooperation by the patient, so that it can be used for detecting strabismus in young children. The method provides a reliable detection of strabismus[1] and has also been used for detecting certain kinds of amblyopia.

Retinal birefringence scanning uses the human eye's birefringent properties to identify the position of the fovea and the direction of gaze, and thereby to measure any binocular misalignment.

Principle

Birefringent material has a refractive index that depends on the polarization state and propagation direction of light.[2][3] The main contribution to the birefringence of the eye stems from the Henle fibers. These fibers (named after Friedrich Gustav Jakob Henle) are photoreceptor axons that are arranged in a radially symmetric pattern, extending outward from the fovea, which is the most sensitive part of the retina. When polarized light strikes the fovea, the layer of Henle fibers produces a characteristic pattern, and the strength and contrast of this pattern as well as the orientation of its bright parts depend on the polarization of the light that reaches the retina.[4] An analysis of this pattern allows the position of the fovea and the direction of gaze to be determined.

Binocular retinal birefringence has been used for diagnosing strabismus (including micro-strabismus) in young children, and has also been proposed for diagnosing amblyopia by detecting strabismus and by detecting a reduced fixation accuracy.[5]

Limitations

However, also birefringent properties of the cornea and the retinal nerve fiber layer (RNFL) are sources of birefringence.[6] Corneal birefringence varies widely from one individual to another, as well as from one location to another for the same individual,[7] and can thus confound measurements.

References

  1. Reed M. Jost; Joost Felius; Eileen E. Birch (August 2014). "High sensitivity of binocular retinal birefringence screening for anisometropic amblyopia without strabismus". Journal of American Association for Pediatric Ophthalmology and Strabismus (JAAPOS). 18 (4): e5–e6. doi:10.1016/j.jaapos.2014.07.017.
  2. Gramatikov BI (2014). "Modern technologies for retinal scanning and imaging: an introduction for the biomedical engineer". Biomedical Engineering Online. 13: 52. doi:10.1186/1475-925X-13-52. PMC 4022984Freely accessible. PMID 24779618.
  3. "Optical Birefringence". Olympus Microscopy Resource Center. Olympus America Inc. Retrieved 2015-12-06.
  4. Gramatikov B (2013). "Detecting fixation on a target using time-frequency distributions of a retinal birefringence scanning signal". Biomedical Engineering Online. 12: 41. doi:10.1186/1475-925X-12-41. PMC 3661397Freely accessible. PMID 23668264.
  5. Loudon SE, Rook CA, Nassif DS, Piskun NV, Hunter DG (2011). "Rapid, high-accuracy detection of strabismus and amblyopia using the pediatric vision scanner". Investigative Ophthalmology & Visual Science. 52 (8): 5043–8. doi:10.1167/iovs.11-7503. PMID 21642624.
  6. GDx-MM: An Imaging Mueller Matrix Retinal Polarimeter. ProQuest. 2007. p. 56. ISBN 978-0-549-27120-8.
  7. Issues in Biomedical Engineering Research and Application: 2013 Edition. ScholarlyEditions. 1 May 2013. p. 297. ISBN 978-1-4901-0871-1.
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